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Monitoring, Logging, and Debugging
- 1: Application Introspection and Debugging
- 2: Auditing
- 3: Debug a StatefulSet
- 4: Debug Init Containers
- 5: Debug Pods and ReplicationControllers
- 6: Debug Running Pods
- 7: Debug Services
- 8: Debugging Kubernetes nodes with crictl
- 9: Determine the Reason for Pod Failure
- 10: Developing and debugging services locally
- 11: Get a Shell to a Running Container
- 12: Monitor Node Health
- 13: Resource metrics pipeline
- 14: Tools for Monitoring Resources
- 15: Troubleshoot Applications
- 16: Troubleshoot Clusters
- 17: Troubleshooting
1 - Application Introspection and Debugging
Once your application is running, you'll inevitably need to debug problems with it.
Earlier we described how you can use kubectl get pods
to retrieve simple status information about
your pods. But there are a number of ways to get even more information about your application.
Using kubectl describe pod
to fetch details about pods
For this example we'll use a Deployment to create two pods, similar to the earlier example.
apiVersion: apps/v1
kind: Deployment
metadata:
name: nginx-deployment
spec:
selector:
matchLabels:
app: nginx
replicas: 2
template:
metadata:
labels:
app: nginx
spec:
containers:
- name: nginx
image: nginx
resources:
limits:
memory: "128Mi"
cpu: "500m"
ports:
- containerPort: 80
Create deployment by running following command:
kubectl apply -f https://k8s.io/examples/application/nginx-with-request.yaml
deployment.apps/nginx-deployment created
Check pod status by following command:
kubectl get pods
NAME READY STATUS RESTARTS AGE
nginx-deployment-1006230814-6winp 1/1 Running 0 11s
nginx-deployment-1006230814-fmgu3 1/1 Running 0 11s
We can retrieve a lot more information about each of these pods using kubectl describe pod
. For example:
kubectl describe pod nginx-deployment-1006230814-6winp
Name: nginx-deployment-1006230814-6winp
Namespace: default
Node: kubernetes-node-wul5/10.240.0.9
Start Time: Thu, 24 Mar 2016 01:39:49 +0000
Labels: app=nginx,pod-template-hash=1006230814
Annotations: kubernetes.io/created-by={"kind":"SerializedReference","apiVersion":"v1","reference":{"kind":"ReplicaSet","namespace":"default","name":"nginx-deployment-1956810328","uid":"14e607e7-8ba1-11e7-b5cb-fa16" ...
Status: Running
IP: 10.244.0.6
Controllers: ReplicaSet/nginx-deployment-1006230814
Containers:
nginx:
Container ID: docker://90315cc9f513c724e9957a4788d3e625a078de84750f244a40f97ae355eb1149
Image: nginx
Image ID: docker://6f62f48c4e55d700cf3eb1b5e33fa051802986b77b874cc351cce539e5163707
Port: 80/TCP
QoS Tier:
cpu: Guaranteed
memory: Guaranteed
Limits:
cpu: 500m
memory: 128Mi
Requests:
memory: 128Mi
cpu: 500m
State: Running
Started: Thu, 24 Mar 2016 01:39:51 +0000
Ready: True
Restart Count: 0
Environment: <none>
Mounts:
/var/run/secrets/kubernetes.io/serviceaccount from default-token-5kdvl (ro)
Conditions:
Type Status
Initialized True
Ready True
PodScheduled True
Volumes:
default-token-4bcbi:
Type: Secret (a volume populated by a Secret)
SecretName: default-token-4bcbi
Optional: false
QoS Class: Guaranteed
Node-Selectors: <none>
Tolerations: <none>
Events:
FirstSeen LastSeen Count From SubobjectPath Type Reason Message
--------- -------- ----- ---- ------------- -------- ------ -------
54s 54s 1 {default-scheduler } Normal Scheduled Successfully assigned nginx-deployment-1006230814-6winp to kubernetes-node-wul5
54s 54s 1 {kubelet kubernetes-node-wul5} spec.containers{nginx} Normal Pulling pulling image "nginx"
53s 53s 1 {kubelet kubernetes-node-wul5} spec.containers{nginx} Normal Pulled Successfully pulled image "nginx"
53s 53s 1 {kubelet kubernetes-node-wul5} spec.containers{nginx} Normal Created Created container with docker id 90315cc9f513
53s 53s 1 {kubelet kubernetes-node-wul5} spec.containers{nginx} Normal Started Started container with docker id 90315cc9f513
Here you can see configuration information about the container(s) and Pod (labels, resource requirements, etc.), as well as status information about the container(s) and Pod (state, readiness, restart count, events, etc.).
The container state is one of Waiting, Running, or Terminated. Depending on the state, additional information will be provided -- here you can see that for a container in Running state, the system tells you when the container started.
Ready tells you whether the container passed its last readiness probe. (In this case, the container does not have a readiness probe configured; the container is assumed to be ready if no readiness probe is configured.)
Restart Count tells you how many times the container has been restarted; this information can be useful for detecting crash loops in containers that are configured with a restart policy of 'always.'
Currently the only Condition associated with a Pod is the binary Ready condition, which indicates that the pod is able to service requests and should be added to the load balancing pools of all matching services.
Lastly, you see a log of recent events related to your Pod. The system compresses multiple identical events by indicating the first and last time it was seen and the number of times it was seen. "From" indicates the component that is logging the event, "SubobjectPath" tells you which object (e.g. container within the pod) is being referred to, and "Reason" and "Message" tell you what happened.
Example: debugging Pending Pods
A common scenario that you can detect using events is when you've created a Pod that won't fit on any node. For example, the Pod might request more resources than are free on any node, or it might specify a label selector that doesn't match any nodes. Let's say we created the previous Deployment with 5 replicas (instead of 2) and requesting 600 millicores instead of 500, on a four-node cluster where each (virtual) machine has 1 CPU. In that case one of the Pods will not be able to schedule. (Note that because of the cluster addon pods such as fluentd, skydns, etc., that run on each node, if we requested 1000 millicores then none of the Pods would be able to schedule.)
kubectl get pods
NAME READY STATUS RESTARTS AGE
nginx-deployment-1006230814-6winp 1/1 Running 0 7m
nginx-deployment-1006230814-fmgu3 1/1 Running 0 7m
nginx-deployment-1370807587-6ekbw 1/1 Running 0 1m
nginx-deployment-1370807587-fg172 0/1 Pending 0 1m
nginx-deployment-1370807587-fz9sd 0/1 Pending 0 1m
To find out why the nginx-deployment-1370807587-fz9sd pod is not running, we can use kubectl describe pod
on the pending Pod and look at its events:
kubectl describe pod nginx-deployment-1370807587-fz9sd
Name: nginx-deployment-1370807587-fz9sd
Namespace: default
Node: /
Labels: app=nginx,pod-template-hash=1370807587
Status: Pending
IP:
Controllers: ReplicaSet/nginx-deployment-1370807587
Containers:
nginx:
Image: nginx
Port: 80/TCP
QoS Tier:
memory: Guaranteed
cpu: Guaranteed
Limits:
cpu: 1
memory: 128Mi
Requests:
cpu: 1
memory: 128Mi
Environment Variables:
Volumes:
default-token-4bcbi:
Type: Secret (a volume populated by a Secret)
SecretName: default-token-4bcbi
Events:
FirstSeen LastSeen Count From SubobjectPath Type Reason Message
--------- -------- ----- ---- ------------- -------- ------ -------
1m 48s 7 {default-scheduler } Warning FailedScheduling pod (nginx-deployment-1370807587-fz9sd) failed to fit in any node
fit failure on node (kubernetes-node-6ta5): Node didn't have enough resource: CPU, requested: 1000, used: 1420, capacity: 2000
fit failure on node (kubernetes-node-wul5): Node didn't have enough resource: CPU, requested: 1000, used: 1100, capacity: 2000
Here you can see the event generated by the scheduler saying that the Pod failed to schedule for reason FailedScheduling
(and possibly others). The message tells us that there were not enough resources for the Pod on any of the nodes.
To correct this situation, you can use kubectl scale
to update your Deployment to specify four or fewer replicas. (Or you could leave the one Pod pending, which is harmless.)
Events such as the ones you saw at the end of kubectl describe pod
are persisted in etcd and provide high-level information on what is happening in the cluster. To list all events you can use
kubectl get events
but you have to remember that events are namespaced. This means that if you're interested in events for some namespaced object (e.g. what happened with Pods in namespace my-namespace
) you need to explicitly provide a namespace to the command:
kubectl get events --namespace=my-namespace
To see events from all namespaces, you can use the --all-namespaces
argument.
In addition to kubectl describe pod
, another way to get extra information about a pod (beyond what is provided by kubectl get pod
) is to pass the -o yaml
output format flag to kubectl get pod
. This will give you, in YAML format, even more information than kubectl describe pod
--essentially all of the information the system has about the Pod. Here you will see things like annotations (which are key-value metadata without the label restrictions, that is used internally by Kubernetes system components), restart policy, ports, and volumes.
kubectl get pod nginx-deployment-1006230814-6winp -o yaml
apiVersion: v1
kind: Pod
metadata:
annotations:
kubernetes.io/created-by: |
{"kind":"SerializedReference","apiVersion":"v1","reference":{"kind":"ReplicaSet","namespace":"default","name":"nginx-deployment-1006230814","uid":"4c84c175-f161-11e5-9a78-42010af00005","apiVersion":"extensions","resourceVersion":"133434"}}
creationTimestamp: 2016-03-24T01:39:50Z
generateName: nginx-deployment-1006230814-
labels:
app: nginx
pod-template-hash: "1006230814"
name: nginx-deployment-1006230814-6winp
namespace: default
resourceVersion: "133447"
uid: 4c879808-f161-11e5-9a78-42010af00005
spec:
containers:
- image: nginx
imagePullPolicy: Always
name: nginx
ports:
- containerPort: 80
protocol: TCP
resources:
limits:
cpu: 500m
memory: 128Mi
requests:
cpu: 500m
memory: 128Mi
terminationMessagePath: /dev/termination-log
volumeMounts:
- mountPath: /var/run/secrets/kubernetes.io/serviceaccount
name: default-token-4bcbi
readOnly: true
dnsPolicy: ClusterFirst
nodeName: kubernetes-node-wul5
restartPolicy: Always
securityContext: {}
serviceAccount: default
serviceAccountName: default
terminationGracePeriodSeconds: 30
volumes:
- name: default-token-4bcbi
secret:
secretName: default-token-4bcbi
status:
conditions:
- lastProbeTime: null
lastTransitionTime: 2016-03-24T01:39:51Z
status: "True"
type: Ready
containerStatuses:
- containerID: docker://90315cc9f513c724e9957a4788d3e625a078de84750f244a40f97ae355eb1149
image: nginx
imageID: docker://6f62f48c4e55d700cf3eb1b5e33fa051802986b77b874cc351cce539e5163707
lastState: {}
name: nginx
ready: true
restartCount: 0
state:
running:
startedAt: 2016-03-24T01:39:51Z
hostIP: 10.240.0.9
phase: Running
podIP: 10.244.0.6
startTime: 2016-03-24T01:39:49Z
Example: debugging a down/unreachable node
Sometimes when debugging it can be useful to look at the status of a node -- for example, because you've noticed strange behavior of a Pod that's running on the node, or to find out why a Pod won't schedule onto the node. As with Pods, you can use kubectl describe node
and kubectl get node -o yaml
to retrieve detailed information about nodes. For example, here's what you'll see if a node is down (disconnected from the network, or kubelet dies and won't restart, etc.). Notice the events that show the node is NotReady, and also notice that the pods are no longer running (they are evicted after five minutes of NotReady status).
kubectl get nodes
NAME STATUS ROLES AGE VERSION
kubernetes-node-861h NotReady <none> 1h v1.13.0
kubernetes-node-bols Ready <none> 1h v1.13.0
kubernetes-node-st6x Ready <none> 1h v1.13.0
kubernetes-node-unaj Ready <none> 1h v1.13.0
kubectl describe node kubernetes-node-861h
Name: kubernetes-node-861h
Role
Labels: kubernetes.io/arch=amd64
kubernetes.io/os=linux
kubernetes.io/hostname=kubernetes-node-861h
Annotations: node.alpha.kubernetes.io/ttl=0
volumes.kubernetes.io/controller-managed-attach-detach=true
Taints: <none>
CreationTimestamp: Mon, 04 Sep 2017 17:13:23 +0800
Phase:
Conditions:
Type Status LastHeartbeatTime LastTransitionTime Reason Message
---- ------ ----------------- ------------------ ------ -------
OutOfDisk Unknown Fri, 08 Sep 2017 16:04:28 +0800 Fri, 08 Sep 2017 16:20:58 +0800 NodeStatusUnknown Kubelet stopped posting node status.
MemoryPressure Unknown Fri, 08 Sep 2017 16:04:28 +0800 Fri, 08 Sep 2017 16:20:58 +0800 NodeStatusUnknown Kubelet stopped posting node status.
DiskPressure Unknown Fri, 08 Sep 2017 16:04:28 +0800 Fri, 08 Sep 2017 16:20:58 +0800 NodeStatusUnknown Kubelet stopped posting node status.
Ready Unknown Fri, 08 Sep 2017 16:04:28 +0800 Fri, 08 Sep 2017 16:20:58 +0800 NodeStatusUnknown Kubelet stopped posting node status.
Addresses: 10.240.115.55,104.197.0.26
Capacity:
cpu: 2
hugePages: 0
memory: 4046788Ki
pods: 110
Allocatable:
cpu: 1500m
hugePages: 0
memory: 1479263Ki
pods: 110
System Info:
Machine ID: 8e025a21a4254e11b028584d9d8b12c4
System UUID: 349075D1-D169-4F25-9F2A-E886850C47E3
Boot ID: 5cd18b37-c5bd-4658-94e0-e436d3f110e0
Kernel Version: 4.4.0-31-generic
OS Image: Debian GNU/Linux 8 (jessie)
Operating System: linux
Architecture: amd64
Container Runtime Version: docker://1.12.5
Kubelet Version: v1.6.9+a3d1dfa6f4335
Kube-Proxy Version: v1.6.9+a3d1dfa6f4335
ExternalID: 15233045891481496305
Non-terminated Pods: (9 in total)
Namespace Name CPU Requests CPU Limits Memory Requests Memory Limits
--------- ---- ------------ ---------- --------------- -------------
......
Allocated resources:
(Total limits may be over 100 percent, i.e., overcommitted.)
CPU Requests CPU Limits Memory Requests Memory Limits
------------ ---------- --------------- -------------
900m (60%) 2200m (146%) 1009286400 (66%) 5681286400 (375%)
Events: <none>
kubectl get node kubernetes-node-861h -o yaml
apiVersion: v1
kind: Node
metadata:
creationTimestamp: 2015-07-10T21:32:29Z
labels:
kubernetes.io/hostname: kubernetes-node-861h
name: kubernetes-node-861h
resourceVersion: "757"
uid: 2a69374e-274b-11e5-a234-42010af0d969
spec:
externalID: "15233045891481496305"
podCIDR: 10.244.0.0/24
providerID: gce://striped-torus-760/us-central1-b/kubernetes-node-861h
status:
addresses:
- address: 10.240.115.55
type: InternalIP
- address: 104.197.0.26
type: ExternalIP
capacity:
cpu: "1"
memory: 3800808Ki
pods: "100"
conditions:
- lastHeartbeatTime: 2015-07-10T21:34:32Z
lastTransitionTime: 2015-07-10T21:35:15Z
reason: Kubelet stopped posting node status.
status: Unknown
type: Ready
nodeInfo:
bootID: 4e316776-b40d-4f78-a4ea-ab0d73390897
containerRuntimeVersion: docker://Unknown
kernelVersion: 3.16.0-0.bpo.4-amd64
kubeProxyVersion: v0.21.1-185-gffc5a86098dc01
kubeletVersion: v0.21.1-185-gffc5a86098dc01
machineID: ""
osImage: Debian GNU/Linux 7 (wheezy)
systemUUID: ABE5F6B4-D44B-108B-C46A-24CCE16C8B6E
What's next
Learn about additional debugging tools, including:
2 - Auditing
Kubernetes auditing provides a security-relevant, chronological set of records documenting the sequence of actions in a cluster. The cluster audits the activities generated by users, by applications that use the Kubernetes API, and by the control plane itself.
Auditing allows cluster administrators to answer the following questions:
- what happened?
- when did it happen?
- who initiated it?
- on what did it happen?
- where was it observed?
- from where was it initiated?
- to where was it going?
Audit records begin their lifecycle inside the kube-apiserver component. Each request on each stage of its execution generates an audit event, which is then pre-processed according to a certain policy and written to a backend. The policy determines what's recorded and the backends persist the records. The current backend implementations include logs files and webhooks.
Each request can be recorded with an associated stage. The defined stages are:
RequestReceived
- The stage for events generated as soon as the audit handler receives the request, and before it is delegated down the handler chain.ResponseStarted
- Once the response headers are sent, but before the response body is sent. This stage is only generated for long-running requests (e.g. watch).ResponseComplete
- The response body has been completed and no more bytes will be sent.Panic
- Events generated when a panic occurred.
Note: The configuration of an Audit Event configuration is different from the Event API object.
The audit logging feature increases the memory consumption of the API server because some context required for auditing is stored for each request. Memory consumption depends on the audit logging configuration.
Audit policy
Audit policy defines rules about what events should be recorded and what data
they should include. The audit policy object structure is defined in the
audit.k8s.io
API group.
When an event is processed, it's
compared against the list of rules in order. The first matching rule sets the
audit level of the event. The defined audit levels are:
None
- don't log events that match this rule.Metadata
- log request metadata (requesting user, timestamp, resource, verb, etc.) but not request or response body.Request
- log event metadata and request body but not response body. This does not apply for non-resource requests.RequestResponse
- log event metadata, request and response bodies. This does not apply for non-resource requests.
You can pass a file with the policy to kube-apiserver
using the --audit-policy-file
flag. If the flag is omitted, no events are logged.
Note that the rules
field must be provided in the audit policy file.
A policy with no (0) rules is treated as illegal.
Below is an example audit policy file:
apiVersion: audit.k8s.io/v1 # This is required.
kind: Policy
# Don't generate audit events for all requests in RequestReceived stage.
omitStages:
- "RequestReceived"
rules:
# Log pod changes at RequestResponse level
- level: RequestResponse
resources:
- group: ""
# Resource "pods" doesn't match requests to any subresource of pods,
# which is consistent with the RBAC policy.
resources: ["pods"]
# Log "pods/log", "pods/status" at Metadata level
- level: Metadata
resources:
- group: ""
resources: ["pods/log", "pods/status"]
# Don't log requests to a configmap called "controller-leader"
- level: None
resources:
- group: ""
resources: ["configmaps"]
resourceNames: ["controller-leader"]
# Don't log watch requests by the "system:kube-proxy" on endpoints or services
- level: None
users: ["system:kube-proxy"]
verbs: ["watch"]
resources:
- group: "" # core API group
resources: ["endpoints", "services"]
# Don't log authenticated requests to certain non-resource URL paths.
- level: None
userGroups: ["system:authenticated"]
nonResourceURLs:
- "/api*" # Wildcard matching.
- "/version"
# Log the request body of configmap changes in kube-system.
- level: Request
resources:
- group: "" # core API group
resources: ["configmaps"]
# This rule only applies to resources in the "kube-system" namespace.
# The empty string "" can be used to select non-namespaced resources.
namespaces: ["kube-system"]
# Log configmap and secret changes in all other namespaces at the Metadata level.
- level: Metadata
resources:
- group: "" # core API group
resources: ["secrets", "configmaps"]
# Log all other resources in core and extensions at the Request level.
- level: Request
resources:
- group: "" # core API group
- group: "extensions" # Version of group should NOT be included.
# A catch-all rule to log all other requests at the Metadata level.
- level: Metadata
# Long-running requests like watches that fall under this rule will not
# generate an audit event in RequestReceived.
omitStages:
- "RequestReceived"
You can use a minimal audit policy file to log all requests at the Metadata
level:
# Log all requests at the Metadata level.
apiVersion: audit.k8s.io/v1
kind: Policy
rules:
- level: Metadata
If you're crafting your own audit profile, you can use the audit profile for Google Container-Optimized OS as a starting point. You can check the configure-helper.sh script, which generates an audit policy file. You can see most of the audit policy file by looking directly at the script.
You can also refer to the Policy
configuration reference
for details about the fields defined.
Audit backends
Audit backends persist audit events to an external storage. Out of the box, the kube-apiserver provides two backends:
- Log backend, which writes events into the filesystem
- Webhook backend, which sends events to an external HTTP API
In all cases, audit events follow a structure defined by the Kubernetes API in the
audit.k8s.io
API group.
Note:In case of patches, request body is a JSON array with patch operations, not a JSON object with an appropriate Kubernetes API object. For example, the following request body is a valid patch request to
/apis/batch/v1/namespaces/some-namespace/jobs/some-job-name
:[ { "op": "replace", "path": "/spec/parallelism", "value": 0 }, { "op": "remove", "path": "/spec/template/spec/containers/0/terminationMessagePolicy" } ]
Log backend
The log backend writes audit events to a file in JSONlines format.
You can configure the log audit backend using the following kube-apiserver
flags:
--audit-log-path
specifies the log file path that log backend uses to write audit events. Not specifying this flag disables log backend.-
means standard out--audit-log-maxage
defined the maximum number of days to retain old audit log files--audit-log-maxbackup
defines the maximum number of audit log files to retain--audit-log-maxsize
defines the maximum size in megabytes of the audit log file before it gets rotated
If your cluster's control plane runs the kube-apiserver as a Pod, remember to mount the hostPath
to the location of the policy file and log file, so that audit records are persisted. For example:
--audit-policy-file=/etc/kubernetes/audit-policy.yaml \
--audit-log-path=/var/log/audit.log
then mount the volumes:
...
volumeMounts:
- mountPath: /etc/kubernetes/audit-policy.yaml
name: audit
readOnly: true
- mountPath: /var/log/audit.log
name: audit-log
readOnly: false
and finally configure the hostPath
:
...
- name: audit
hostPath:
path: /etc/kubernetes/audit-policy.yaml
type: File
- name: audit-log
hostPath:
path: /var/log/audit.log
type: FileOrCreate
Webhook backend
The webhook audit backend sends audit events to a remote web API, which is assumed to be a form of the Kubernetes API, including means of authentication. You can configure a webhook audit backend using the following kube-apiserver flags:
--audit-webhook-config-file
specifies the path to a file with a webhook configuration. The webhook configuration is effectively a specialized kubeconfig.--audit-webhook-initial-backoff
specifies the amount of time to wait after the first failed request before retrying. Subsequent requests are retried with exponential backoff.
The webhook config file uses the kubeconfig format to specify the remote address of the service and credentials used to connect to it.
Event batching
Both log and webhook backends support batching. Using webhook as an example, here's the list of
available flags. To get the same flag for log backend, replace webhook
with log
in the flag
name. By default, batching is enabled in webhook
and disabled in log
. Similarly, by default
throttling is enabled in webhook
and disabled in log
.
--audit-webhook-mode
defines the buffering strategy. One of the following:batch
- buffer events and asynchronously process them in batches. This is the default.blocking
- block API server responses on processing each individual event.blocking-strict
- Same as blocking, but when there is a failure during audit logging at the RequestReceived stage, the whole request to the kube-apiserver fails.
The following flags are used only in the batch
mode:
--audit-webhook-batch-buffer-size
defines the number of events to buffer before batching. If the rate of incoming events overflows the buffer, events are dropped.--audit-webhook-batch-max-size
defines the maximum number of events in one batch.--audit-webhook-batch-max-wait
defines the maximum amount of time to wait before unconditionally batching events in the queue.--audit-webhook-batch-throttle-qps
defines the maximum average number of batches generated per second.--audit-webhook-batch-throttle-burst
defines the maximum number of batches generated at the same moment if the allowed QPS was underutilized previously.
Parameter tuning
Parameters should be set to accommodate the load on the API server.
For example, if kube-apiserver receives 100 requests each second, and each request is audited only
on ResponseStarted
and ResponseComplete
stages, you should account for ≅200 audit
events being generated each second. Assuming that there are up to 100 events in a batch,
you should set throttling level at least 2 queries per second. Assuming that the backend can take up to
5 seconds to write events, you should set the buffer size to hold up to 5 seconds of events;
that is: 10 batches, or 1000 events.
In most cases however, the default parameters should be sufficient and you don't have to worry about setting them manually. You can look at the following Prometheus metrics exposed by kube-apiserver and in the logs to monitor the state of the auditing subsystem.
apiserver_audit_event_total
metric contains the total number of audit events exported.apiserver_audit_error_total
metric contains the total number of events dropped due to an error during exporting.
Log entry truncation
Both log and webhook backends support limiting the size of events that are logged. As an example, the following is the list of flags available for the log backend:
audit-log-truncate-enabled
whether event and batch truncating is enabled.audit-log-truncate-max-batch-size
maximum size in bytes of the batch sent to the underlying backend.audit-log-truncate-max-event-size
maximum size in bytes of the audit event sent to the underlying backend.
By default truncate is disabled in both webhook
and log
, a cluster administrator should set
audit-log-truncate-enabled
or audit-webhook-truncate-enabled
to enable the feature.
What's next
- Learn about Mutating webhook auditing annotations.
- Learn more about
Event
and thePolicy
resource types by reading the Audit configuration reference.
3 - Debug a StatefulSet
This task shows you how to debug a StatefulSet.
Before you begin
- You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster.
- You should have a StatefulSet running that you want to investigate.
Debugging a StatefulSet
In order to list all the pods which belong to a StatefulSet, which have a label app=myapp
set on them,
you can use the following:
kubectl get pods -l app=myapp
If you find that any Pods listed are in Unknown
or Terminating
state for an extended period of time,
refer to the Deleting StatefulSet Pods task for
instructions on how to deal with them.
You can debug individual Pods in a StatefulSet using the
Debugging Pods guide.
What's next
Learn more about debugging an init-container.
4 - Debug Init Containers
This page shows how to investigate problems related to the execution of
Init Containers. The example command lines below refer to the Pod as
<pod-name>
and the Init Containers as <init-container-1>
and
<init-container-2>
.
Before you begin
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
To check the version, enterkubectl version
.- You should be familiar with the basics of Init Containers.
- You should have Configured an Init Container.
Checking the status of Init Containers
Display the status of your pod:
kubectl get pod <pod-name>
For example, a status of Init:1/2
indicates that one of two Init Containers
has completed successfully:
NAME READY STATUS RESTARTS AGE
<pod-name> 0/1 Init:1/2 0 7s
See Understanding Pod status for more examples of status values and their meanings.
Getting details about Init Containers
View more detailed information about Init Container execution:
kubectl describe pod <pod-name>
For example, a Pod with two Init Containers might show the following:
Init Containers:
<init-container-1>:
Container ID: ...
...
State: Terminated
Reason: Completed
Exit Code: 0
Started: ...
Finished: ...
Ready: True
Restart Count: 0
...
<init-container-2>:
Container ID: ...
...
State: Waiting
Reason: CrashLoopBackOff
Last State: Terminated
Reason: Error
Exit Code: 1
Started: ...
Finished: ...
Ready: False
Restart Count: 3
...
You can also access the Init Container statuses programmatically by reading the
status.initContainerStatuses
field on the Pod Spec:
kubectl get pod nginx --template '{{.status.initContainerStatuses}}'
This command will return the same information as above in raw JSON.
Accessing logs from Init Containers
Pass the Init Container name along with the Pod name to access its logs.
kubectl logs <pod-name> -c <init-container-2>
Init Containers that run a shell script print
commands as they're executed. For example, you can do this in Bash by running
set -x
at the beginning of the script.
Understanding Pod status
A Pod status beginning with Init:
summarizes the status of Init Container
execution. The table below describes some example status values that you might
see while debugging Init Containers.
Status | Meaning |
---|---|
Init:N/M | The Pod has M Init Containers, and N have completed so far. |
Init:Error | An Init Container has failed to execute. |
Init:CrashLoopBackOff | An Init Container has failed repeatedly. |
Pending | The Pod has not yet begun executing Init Containers. |
PodInitializing or Running | The Pod has already finished executing Init Containers. |
5 - Debug Pods and ReplicationControllers
This page shows how to debug Pods and ReplicationControllers.
Before you begin
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
To check the version, enterkubectl version
.- You should be familiar with the basics of Pods and with Pods' lifecycles.
Debugging Pods
The first step in debugging a pod is taking a look at it. Check the current state of the pod and recent events with the following command:
kubectl describe pods ${POD_NAME}
Look at the state of the containers in the pod. Are they all Running
? Have
there been recent restarts?
Continue debugging depending on the state of the pods.
My pod stays pending
If a pod is stuck in Pending
it means that it can not be scheduled onto a
node. Generally this is because there are insufficient resources of one type or
another that prevent scheduling. Look at the output of the kubectl describe ...
command above. There should be messages from the scheduler about why it
can not schedule your pod. Reasons include:
Insufficient resources
You may have exhausted the supply of CPU or Memory in your cluster. In this case you can try several things:
Add more nodes to the cluster.
Terminate unneeded pods to make room for pending pods.
Check that the pod is not larger than your nodes. For example, if all nodes have a capacity of
cpu:1
, then a pod with a request ofcpu: 1.1
will never be scheduled.You can check node capacities with the
kubectl get nodes -o <format>
command. Here are some example command lines that extract the necessary information:kubectl get nodes -o yaml | egrep '\sname:|cpu:|memory:' kubectl get nodes -o json | jq '.items[] | {name: .metadata.name, cap: .status.capacity}'
The resource quota feature can be configured to limit the total amount of resources that can be consumed. If used in conjunction with namespaces, it can prevent one team from hogging all the resources.
Using hostPort
When you bind a pod to a hostPort
there are a limited number of places that
the pod can be scheduled. In most cases, hostPort
is unnecessary; try using a
service object to expose your pod. If you do require hostPort
then you can
only schedule as many pods as there are nodes in your container cluster.
My pod stays waiting
If a pod is stuck in the Waiting
state, then it has been scheduled to a
worker node, but it can't run on that machine. Again, the information from
kubectl describe ...
should be informative. The most common cause of
Waiting
pods is a failure to pull the image. There are three things to check:
- Make sure that you have the name of the image correct.
- Have you pushed the image to the repository?
- Run a manual
docker pull <image>
on your machine to see if the image can be pulled.
My pod is crashing or otherwise unhealthy
Once your pod has been scheduled, the methods described in Debug Running Pods are available for debugging.
Debugging ReplicationControllers
ReplicationControllers are fairly straightforward. They can either create pods or they can't. If they can't create pods, then please refer to the instructions above to debug your pods.
You can also use kubectl describe rc ${CONTROLLER_NAME}
to inspect events
related to the replication controller.
6 - Debug Running Pods
This page explains how to debug Pods running (or crashing) on a Node.
Before you begin
- Your Pod should already be scheduled and running. If your Pod is not yet running, start with Troubleshoot Applications.
- For some of the advanced debugging steps you need to know on which Node the
Pod is running and have shell access to run commands on that Node. You don't
need that access to run the standard debug steps that use
kubectl
.
Examining pod logs
First, look at the logs of the affected container:
kubectl logs ${POD_NAME} ${CONTAINER_NAME}
If your container has previously crashed, you can access the previous container's crash log with:
kubectl logs --previous ${POD_NAME} ${CONTAINER_NAME}
Debugging with container exec
If the container image includes
debugging utilities, as is the case with images built from Linux and Windows OS
base images, you can run commands inside a specific container with
kubectl exec
:
kubectl exec ${POD_NAME} -c ${CONTAINER_NAME} -- ${CMD} ${ARG1} ${ARG2} ... ${ARGN}
Note:-c ${CONTAINER_NAME}
is optional. You can omit it for Pods that only contain a single container.
As an example, to look at the logs from a running Cassandra pod, you might run
kubectl exec cassandra -- cat /var/log/cassandra/system.log
You can run a shell that's connected to your terminal using the -i
and -t
arguments to kubectl exec
, for example:
kubectl exec -it cassandra -- sh
For more details, see Get a Shell to a Running Container.
Debugging with an ephemeral debug container
Kubernetes v1.18 [alpha]
Ephemeral containers
are useful for interactive troubleshooting when kubectl exec
is insufficient
because a container has crashed or a container image doesn't include debugging
utilities, such as with distroless images. kubectl
has an alpha
command that can create ephemeral containers for debugging beginning with version
v1.18
.
Example debugging using ephemeral containers
Note: The examples in this section require theEphemeralContainers
feature gate enabled in your cluster andkubectl
version v1.18 or later.
You can use the kubectl debug
command to add ephemeral containers to a
running Pod. First, create a pod for the example:
kubectl run ephemeral-demo --image=k8s.gcr.io/pause:3.1 --restart=Never
The examples in this section use the pause
container image because it does not
contain debugging utilities, but this method works with all container
images.
If you attempt to use kubectl exec
to create a shell you will see an error
because there is no shell in this container image.
kubectl exec -it ephemeral-demo -- sh
OCI runtime exec failed: exec failed: container_linux.go:346: starting container process caused "exec: \"sh\": executable file not found in $PATH": unknown
You can instead add a debugging container using kubectl debug
. If you
specify the -i
/--interactive
argument, kubectl
will automatically attach
to the console of the Ephemeral Container.
kubectl debug -it ephemeral-demo --image=busybox --target=ephemeral-demo
Defaulting debug container name to debugger-8xzrl.
If you don't see a command prompt, try pressing enter.
/ #
This command adds a new busybox container and attaches to it. The --target
parameter targets the process namespace of another container. It's necessary
here because kubectl run
does not enable process namespace sharing in the pod it
creates.
Note: The--target
parameter must be supported by the Container Runtime. When not supported, the Ephemeral Container may not be started, or it may be started with an isolated process namespace.
You can view the state of the newly created ephemeral container using kubectl describe
:
kubectl describe pod ephemeral-demo
...
Ephemeral Containers:
debugger-8xzrl:
Container ID: docker://b888f9adfd15bd5739fefaa39e1df4dd3c617b9902082b1cfdc29c4028ffb2eb
Image: busybox
Image ID: docker-pullable://busybox@sha256:1828edd60c5efd34b2bf5dd3282ec0cc04d47b2ff9caa0b6d4f07a21d1c08084
Port: <none>
Host Port: <none>
State: Running
Started: Wed, 12 Feb 2020 14:25:42 +0100
Ready: False
Restart Count: 0
Environment: <none>
Mounts: <none>
...
Use kubectl delete
to remove the Pod when you're finished:
kubectl delete pod ephemeral-demo
Debugging using a copy of the Pod
Sometimes Pod configuration options make it difficult to troubleshoot in certain
situations. For example, you can't run kubectl exec
to troubleshoot your
container if your container image does not include a shell or if your application
crashes on startup. In these situations you can use kubectl debug
to create a
copy of the Pod with configuration values changed to aid debugging.
Copying a Pod while adding a new container
Adding a new container can be useful when your application is running but not behaving as you expect and you'd like to add additional troubleshooting utilities to the Pod.
For example, maybe your application's container images are built on busybox
but you need debugging utilities not included in busybox
. You can simulate
this scenario using kubectl run
:
kubectl run myapp --image=busybox --restart=Never -- sleep 1d
Run this command to create a copy of myapp
named myapp-debug
that adds a
new Ubuntu container for debugging:
kubectl debug myapp -it --image=ubuntu --share-processes --copy-to=myapp-debug
Defaulting debug container name to debugger-w7xmf.
If you don't see a command prompt, try pressing enter.
root@myapp-debug:/#
Note:
kubectl debug
automatically generates a container name if you don't choose one using the--container
flag.- The
-i
flag causeskubectl debug
to attach to the new container by default. You can prevent this by specifying--attach=false
. If your session becomes disconnected you can reattach usingkubectl attach
.- The
--share-processes
allows the containers in this Pod to see processes from the other containers in the Pod. For more information about how this works, see Share Process Namespace between Containers in a Pod.
Don't forget to clean up the debugging Pod when you're finished with it:
kubectl delete pod myapp myapp-debug
Copying a Pod while changing its command
Sometimes it's useful to change the command for a container, for example to add a debugging flag or because the application is crashing.
To simulate a crashing application, use kubectl run
to create a container
that immediately exits:
kubectl run --image=busybox myapp -- false
You can see using kubectl describe pod myapp
that this container is crashing:
Containers:
myapp:
Image: busybox
...
Args:
false
State: Waiting
Reason: CrashLoopBackOff
Last State: Terminated
Reason: Error
Exit Code: 1
You can use kubectl debug
to create a copy of this Pod with the command
changed to an interactive shell:
kubectl debug myapp -it --copy-to=myapp-debug --container=myapp -- sh
If you don't see a command prompt, try pressing enter.
/ #
Now you have an interactive shell that you can use to perform tasks like checking filesystem paths or running the container command manually.
Note:
- To change the command of a specific container you must specify its name using
--container
orkubectl debug
will instead create a new container to run the command you specified.- The
-i
flag causeskubectl debug
to attach to the container by default. You can prevent this by specifying--attach=false
. If your session becomes disconnected you can reattach usingkubectl attach
.
Don't forget to clean up the debugging Pod when you're finished with it:
kubectl delete pod myapp myapp-debug
Copying a Pod while changing container images
In some situations you may want to change a misbehaving Pod from its normal production container images to an image containing a debugging build or additional utilities.
As an example, create a Pod using kubectl run
:
kubectl run myapp --image=busybox --restart=Never -- sleep 1d
Now use kubectl debug
to make a copy and change its container image
to ubuntu
:
kubectl debug myapp --copy-to=myapp-debug --set-image=*=ubuntu
The syntax of --set-image
uses the same container_name=image
syntax as
kubectl set image
. *=ubuntu
means change the image of all containers
to ubuntu
.
Don't forget to clean up the debugging Pod when you're finished with it:
kubectl delete pod myapp myapp-debug
Debugging via a shell on the node
If none of these approaches work, you can find the Node on which the Pod is
running and create a privileged Pod running in the host namespaces. To create
an interactive shell on a node using kubectl debug
, run:
kubectl debug node/mynode -it --image=ubuntu
Creating debugging pod node-debugger-mynode-pdx84 with container debugger on node mynode.
If you don't see a command prompt, try pressing enter.
root@ek8s:/#
When creating a debugging session on a node, keep in mind that:
kubectl debug
automatically generates the name of the new Pod based on the name of the Node.- The container runs in the host IPC, Network, and PID namespaces.
- The root filesystem of the Node will be mounted at
/host
.
Don't forget to clean up the debugging Pod when you're finished with it:
kubectl delete pod node-debugger-mynode-pdx84
7 - Debug Services
An issue that comes up rather frequently for new installations of Kubernetes is that a Service is not working properly. You've run your Pods through a Deployment (or other workload controller) and created a Service, but you get no response when you try to access it. This document will hopefully help you to figure out what's going wrong.
Running commands in a Pod
For many steps here you will want to see what a Pod running in the cluster sees. The simplest way to do this is to run an interactive busybox Pod:
kubectl run -it --rm --restart=Never busybox --image=gcr.io/google-containers/busybox sh
Note: If you don't see a command prompt, try pressing enter.
If you already have a running Pod that you prefer to use, you can run a command in it using:
kubectl exec <POD-NAME> -c <CONTAINER-NAME> -- <COMMAND>
Setup
For the purposes of this walk-through, let's run some Pods. Since you're probably debugging your own Service you can substitute your own details, or you can follow along and get a second data point.
kubectl create deployment hostnames --image=k8s.gcr.io/serve_hostname
deployment.apps/hostnames created
kubectl
commands will print the type and name of the resource created or mutated, which can then be used in subsequent commands.
Let's scale the deployment to 3 replicas.
kubectl scale deployment hostnames --replicas=3
deployment.apps/hostnames scaled
Note that this is the same as if you had started the Deployment with the following YAML:
apiVersion: apps/v1
kind: Deployment
metadata:
labels:
app: hostnames
name: hostnames
spec:
selector:
matchLabels:
app: hostnames
replicas: 3
template:
metadata:
labels:
app: hostnames
spec:
containers:
- name: hostnames
image: k8s.gcr.io/serve_hostname
The label "app" is automatically set by kubectl create deployment
to the name of the
Deployment.
You can confirm your Pods are running:
kubectl get pods -l app=hostnames
NAME READY STATUS RESTARTS AGE
hostnames-632524106-bbpiw 1/1 Running 0 2m
hostnames-632524106-ly40y 1/1 Running 0 2m
hostnames-632524106-tlaok 1/1 Running 0 2m
You can also confirm that your Pods are serving. You can get the list of Pod IP addresses and test them directly.
kubectl get pods -l app=hostnames \
-o go-template='{{range .items}}{{.status.podIP}}{{"\n"}}{{end}}'
10.244.0.5
10.244.0.6
10.244.0.7
The example container used for this walk-through serves its own hostname via HTTP on port 9376, but if you are debugging your own app, you'll want to use whatever port number your Pods are listening on.
From within a pod:
for ep in 10.244.0.5:9376 10.244.0.6:9376 10.244.0.7:9376; do
wget -qO- $ep
done
This should produce something like:
hostnames-632524106-bbpiw
hostnames-632524106-ly40y
hostnames-632524106-tlaok
If you are not getting the responses you expect at this point, your Pods
might not be healthy or might not be listening on the port you think they are.
You might find kubectl logs
to be useful for seeing what is happening, or
perhaps you need to kubectl exec
directly into your Pods and debug from
there.
Assuming everything has gone to plan so far, you can start to investigate why your Service doesn't work.
Does the Service exist?
The astute reader will have noticed that you did not actually create a Service yet - that is intentional. This is a step that sometimes gets forgotten, and is the first thing to check.
What would happen if you tried to access a non-existent Service? If you have another Pod that consumes this Service by name you would get something like:
wget -O- hostnames
Resolving hostnames (hostnames)... failed: Name or service not known.
wget: unable to resolve host address 'hostnames'
The first thing to check is whether that Service actually exists:
kubectl get svc hostnames
No resources found.
Error from server (NotFound): services "hostnames" not found
Let's create the Service. As before, this is for the walk-through - you can use your own Service's details here.
kubectl expose deployment hostnames --port=80 --target-port=9376
service/hostnames exposed
And read it back:
kubectl get svc hostnames
NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE
hostnames ClusterIP 10.0.1.175 <none> 80/TCP 5s
Now you know that the Service exists.
As before, this is the same as if you had started the Service with YAML:
apiVersion: v1
kind: Service
metadata:
labels:
app: hostnames
name: hostnames
spec:
selector:
app: hostnames
ports:
- name: default
protocol: TCP
port: 80
targetPort: 9376
In order to highlight the full range of configuration, the Service you created here uses a different port number than the Pods. For many real-world Services, these values might be the same.
Does the Service work by DNS name?
One of the most common ways that clients consume a Service is through a DNS name.
From a Pod in the same Namespace:
nslookup hostnames
Address 1: 10.0.0.10 kube-dns.kube-system.svc.cluster.local
Name: hostnames
Address 1: 10.0.1.175 hostnames.default.svc.cluster.local
If this fails, perhaps your Pod and Service are in different Namespaces, try a namespace-qualified name (again, from within a Pod):
nslookup hostnames.default
Address 1: 10.0.0.10 kube-dns.kube-system.svc.cluster.local
Name: hostnames.default
Address 1: 10.0.1.175 hostnames.default.svc.cluster.local
If this works, you'll need to adjust your app to use a cross-namespace name, or run your app and Service in the same Namespace. If this still fails, try a fully-qualified name:
nslookup hostnames.default.svc.cluster.local
Address 1: 10.0.0.10 kube-dns.kube-system.svc.cluster.local
Name: hostnames.default.svc.cluster.local
Address 1: 10.0.1.175 hostnames.default.svc.cluster.local
Note the suffix here: "default.svc.cluster.local". The "default" is the Namespace you're operating in. The "svc" denotes that this is a Service. The "cluster.local" is your cluster domain, which COULD be different in your own cluster.
You can also try this from a Node in the cluster:
Note: 10.0.0.10 is the cluster's DNS Service IP, yours might be different.
nslookup hostnames.default.svc.cluster.local 10.0.0.10
Server: 10.0.0.10
Address: 10.0.0.10#53
Name: hostnames.default.svc.cluster.local
Address: 10.0.1.175
If you are able to do a fully-qualified name lookup but not a relative one, you
need to check that your /etc/resolv.conf
file in your Pod is correct. From
within a Pod:
cat /etc/resolv.conf
You should see something like:
nameserver 10.0.0.10
search default.svc.cluster.local svc.cluster.local cluster.local example.com
options ndots:5
The nameserver
line must indicate your cluster's DNS Service. This is
passed into kubelet
with the --cluster-dns
flag.
The search
line must include an appropriate suffix for you to find the
Service name. In this case it is looking for Services in the local
Namespace ("default.svc.cluster.local"), Services in all Namespaces
("svc.cluster.local"), and lastly for names in the cluster ("cluster.local").
Depending on your own install you might have additional records after that (up
to 6 total). The cluster suffix is passed into kubelet
with the
--cluster-domain
flag. Throughout this document, the cluster suffix is
assumed to be "cluster.local". Your own clusters might be configured
differently, in which case you should change that in all of the previous
commands.
The options
line must set ndots
high enough that your DNS client library
considers search paths at all. Kubernetes sets this to 5 by default, which is
high enough to cover all of the DNS names it generates.
Does any Service work by DNS name?
If the above still fails, DNS lookups are not working for your Service. You can take a step back and see what else is not working. The Kubernetes master Service should always work. From within a Pod:
nslookup kubernetes.default
Server: 10.0.0.10
Address 1: 10.0.0.10 kube-dns.kube-system.svc.cluster.local
Name: kubernetes.default
Address 1: 10.0.0.1 kubernetes.default.svc.cluster.local
If this fails, please see the kube-proxy section of this document, or even go back to the top of this document and start over, but instead of debugging your own Service, debug the DNS Service.
Does the Service work by IP?
Assuming you have confirmed that DNS works, the next thing to test is whether your
Service works by its IP address. From a Pod in your cluster, access the
Service's IP (from kubectl get
above).
for i in $(seq 1 3); do
wget -qO- 10.0.1.175:80
done
This should produce something like:
hostnames-632524106-bbpiw
hostnames-632524106-ly40y
hostnames-632524106-tlaok
If your Service is working, you should get correct responses. If not, there are a number of things that could be going wrong. Read on.
Is the Service defined correctly?
It might sound silly, but you should really double and triple check that your Service is correct and matches your Pod's port. Read back your Service and verify it:
kubectl get service hostnames -o json
{
"kind": "Service",
"apiVersion": "v1",
"metadata": {
"name": "hostnames",
"namespace": "default",
"uid": "428c8b6c-24bc-11e5-936d-42010af0a9bc",
"resourceVersion": "347189",
"creationTimestamp": "2015-07-07T15:24:29Z",
"labels": {
"app": "hostnames"
}
},
"spec": {
"ports": [
{
"name": "default",
"protocol": "TCP",
"port": 80,
"targetPort": 9376,
"nodePort": 0
}
],
"selector": {
"app": "hostnames"
},
"clusterIP": "10.0.1.175",
"type": "ClusterIP",
"sessionAffinity": "None"
},
"status": {
"loadBalancer": {}
}
}
- Is the Service port you are trying to access listed in
spec.ports[]
? - Is the
targetPort
correct for your Pods (some Pods use a different port than the Service)? - If you meant to use a numeric port, is it a number (9376) or a string "9376"?
- If you meant to use a named port, do your Pods expose a port with the same name?
- Is the port's
protocol
correct for your Pods?
Does the Service have any Endpoints?
If you got this far, you have confirmed that your Service is correctly defined and is resolved by DNS. Now let's check that the Pods you ran are actually being selected by the Service.
Earlier you saw that the Pods were running. You can re-check that:
kubectl get pods -l app=hostnames
NAME READY STATUS RESTARTS AGE
hostnames-632524106-bbpiw 1/1 Running 0 1h
hostnames-632524106-ly40y 1/1 Running 0 1h
hostnames-632524106-tlaok 1/1 Running 0 1h
The -l app=hostnames
argument is a label selector configured on the Service.
The "AGE" column says that these Pods are about an hour old, which implies that they are running fine and not crashing.
The "RESTARTS" column says that these pods are not crashing frequently or being restarted. Frequent restarts could lead to intermittent connectivity issues. If the restart count is high, read more about how to debug pods.
Inside the Kubernetes system is a control loop which evaluates the selector of every Service and saves the results into a corresponding Endpoints object.
kubectl get endpoints hostnames
NAME ENDPOINTS
hostnames 10.244.0.5:9376,10.244.0.6:9376,10.244.0.7:9376
This confirms that the endpoints controller has found the correct Pods for
your Service. If the ENDPOINTS
column is <none>
, you should check that
the spec.selector
field of your Service actually selects for
metadata.labels
values on your Pods. A common mistake is to have a typo or
other error, such as the Service selecting for app=hostnames
, but the
Deployment specifying run=hostnames
, as in versions previous to 1.18, where
the kubectl run
command could have been also used to create a Deployment.
Are the Pods working?
At this point, you know that your Service exists and has selected your Pods. At the beginning of this walk-through, you verified the Pods themselves. Let's check again that the Pods are actually working - you can bypass the Service mechanism and go straight to the Pods, as listed by the Endpoints above.
Note: These commands use the Pod port (9376), rather than the Service port (80).
From within a Pod:
for ep in 10.244.0.5:9376 10.244.0.6:9376 10.244.0.7:9376; do
wget -qO- $ep
done
This should produce something like:
hostnames-632524106-bbpiw
hostnames-632524106-ly40y
hostnames-632524106-tlaok
You expect each Pod in the Endpoints list to return its own hostname. If this is not what happens (or whatever the correct behavior is for your own Pods), you should investigate what's happening there.
Is the kube-proxy working?
If you get here, your Service is running, has Endpoints, and your Pods are actually serving. At this point, the whole Service proxy mechanism is suspect. Let's confirm it, piece by piece.
The default implementation of Services, and the one used on most clusters, is kube-proxy. This is a program that runs on every node and configures one of a small set of mechanisms for providing the Service abstraction. If your cluster does not use kube-proxy, the following sections will not apply, and you will have to investigate whatever implementation of Services you are using.
Is kube-proxy running?
Confirm that kube-proxy
is running on your Nodes. Running directly on a
Node, you should get something like the below:
ps auxw | grep kube-proxy
root 4194 0.4 0.1 101864 17696 ? Sl Jul04 25:43 /usr/local/bin/kube-proxy --master=https://kubernetes-master --kubeconfig=/var/lib/kube-proxy/kubeconfig --v=2
Next, confirm that it is not failing something obvious, like contacting the
master. To do this, you'll have to look at the logs. Accessing the logs
depends on your Node OS. On some OSes it is a file, such as
/var/log/kube-proxy.log, while other OSes use journalctl
to access logs. You
should see something like:
I1027 22:14:53.995134 5063 server.go:200] Running in resource-only container "/kube-proxy"
I1027 22:14:53.998163 5063 server.go:247] Using iptables Proxier.
I1027 22:14:53.999055 5063 server.go:255] Tearing down userspace rules. Errors here are acceptable.
I1027 22:14:54.038140 5063 proxier.go:352] Setting endpoints for "kube-system/kube-dns:dns-tcp" to [10.244.1.3:53]
I1027 22:14:54.038164 5063 proxier.go:352] Setting endpoints for "kube-system/kube-dns:dns" to [10.244.1.3:53]
I1027 22:14:54.038209 5063 proxier.go:352] Setting endpoints for "default/kubernetes:https" to [10.240.0.2:443]
I1027 22:14:54.038238 5063 proxier.go:429] Not syncing iptables until Services and Endpoints have been received from master
I1027 22:14:54.040048 5063 proxier.go:294] Adding new service "default/kubernetes:https" at 10.0.0.1:443/TCP
I1027 22:14:54.040154 5063 proxier.go:294] Adding new service "kube-system/kube-dns:dns" at 10.0.0.10:53/UDP
I1027 22:14:54.040223 5063 proxier.go:294] Adding new service "kube-system/kube-dns:dns-tcp" at 10.0.0.10:53/TCP
If you see error messages about not being able to contact the master, you should double-check your Node configuration and installation steps.
One of the possible reasons that kube-proxy
cannot run correctly is that the
required conntrack
binary cannot be found. This may happen on some Linux
systems, depending on how you are installing the cluster, for example, you are
installing Kubernetes from scratch. If this is the case, you need to manually
install the conntrack
package (e.g. sudo apt install conntrack
on Ubuntu)
and then retry.
Kube-proxy can run in one of a few modes. In the log listed above, the
line Using iptables Proxier
indicates that kube-proxy is running in
"iptables" mode. The most common other mode is "ipvs". The older "userspace"
mode has largely been replaced by these.
Iptables mode
In "iptables" mode, you should see something like the following on a Node:
iptables-save | grep hostnames
-A KUBE-SEP-57KPRZ3JQVENLNBR -s 10.244.3.6/32 -m comment --comment "default/hostnames:" -j MARK --set-xmark 0x00004000/0x00004000
-A KUBE-SEP-57KPRZ3JQVENLNBR -p tcp -m comment --comment "default/hostnames:" -m tcp -j DNAT --to-destination 10.244.3.6:9376
-A KUBE-SEP-WNBA2IHDGP2BOBGZ -s 10.244.1.7/32 -m comment --comment "default/hostnames:" -j MARK --set-xmark 0x00004000/0x00004000
-A KUBE-SEP-WNBA2IHDGP2BOBGZ -p tcp -m comment --comment "default/hostnames:" -m tcp -j DNAT --to-destination 10.244.1.7:9376
-A KUBE-SEP-X3P2623AGDH6CDF3 -s 10.244.2.3/32 -m comment --comment "default/hostnames:" -j MARK --set-xmark 0x00004000/0x00004000
-A KUBE-SEP-X3P2623AGDH6CDF3 -p tcp -m comment --comment "default/hostnames:" -m tcp -j DNAT --to-destination 10.244.2.3:9376
-A KUBE-SERVICES -d 10.0.1.175/32 -p tcp -m comment --comment "default/hostnames: cluster IP" -m tcp --dport 80 -j KUBE-SVC-NWV5X2332I4OT4T3
-A KUBE-SVC-NWV5X2332I4OT4T3 -m comment --comment "default/hostnames:" -m statistic --mode random --probability 0.33332999982 -j KUBE-SEP-WNBA2IHDGP2BOBGZ
-A KUBE-SVC-NWV5X2332I4OT4T3 -m comment --comment "default/hostnames:" -m statistic --mode random --probability 0.50000000000 -j KUBE-SEP-X3P2623AGDH6CDF3
-A KUBE-SVC-NWV5X2332I4OT4T3 -m comment --comment "default/hostnames:" -j KUBE-SEP-57KPRZ3JQVENLNBR
For each port of each Service, there should be 1 rule in KUBE-SERVICES
and
one KUBE-SVC-<hash>
chain. For each Pod endpoint, there should be a small
number of rules in that KUBE-SVC-<hash>
and one KUBE-SEP-<hash>
chain with
a small number of rules in it. The exact rules will vary based on your exact
config (including node-ports and load-balancers).
IPVS mode
In "ipvs" mode, you should see something like the following on a Node:
ipvsadm -ln
Prot LocalAddress:Port Scheduler Flags
-> RemoteAddress:Port Forward Weight ActiveConn InActConn
...
TCP 10.0.1.175:80 rr
-> 10.244.0.5:9376 Masq 1 0 0
-> 10.244.0.6:9376 Masq 1 0 0
-> 10.244.0.7:9376 Masq 1 0 0
...
For each port of each Service, plus any NodePorts, external IPs, and
load-balancer IPs, kube-proxy will create a virtual server. For each Pod
endpoint, it will create corresponding real servers. In this example, service
hostnames(10.0.1.175:80
) has 3 endpoints(10.244.0.5:9376
,
10.244.0.6:9376
, 10.244.0.7:9376
).
Userspace mode
In rare cases, you may be using "userspace" mode. From your Node:
iptables-save | grep hostnames
-A KUBE-PORTALS-CONTAINER -d 10.0.1.175/32 -p tcp -m comment --comment "default/hostnames:default" -m tcp --dport 80 -j REDIRECT --to-ports 48577
-A KUBE-PORTALS-HOST -d 10.0.1.175/32 -p tcp -m comment --comment "default/hostnames:default" -m tcp --dport 80 -j DNAT --to-destination 10.240.115.247:48577
There should be 2 rules for each port of your Service (only one in this example) - a "KUBE-PORTALS-CONTAINER" and a "KUBE-PORTALS-HOST".
Almost nobody should be using the "userspace" mode any more, so you won't spend more time on it here.
Is kube-proxy proxying?
Assuming you do see one the above cases, try again to access your Service by IP from one of your Nodes:
curl 10.0.1.175:80
hostnames-632524106-bbpiw
If this fails and you are using the userspace proxy, you can try accessing the proxy directly. If you are using the iptables proxy, skip this section.
Look back at the iptables-save
output above, and extract the
port number that kube-proxy
is using for your Service. In the above
examples it is "48577". Now connect to that:
curl localhost:48577
hostnames-632524106-tlaok
If this still fails, look at the kube-proxy
logs for specific lines like:
Setting endpoints for default/hostnames:default to [10.244.0.5:9376 10.244.0.6:9376 10.244.0.7:9376]
If you don't see those, try restarting kube-proxy
with the -v
flag set to 4, and
then look at the logs again.
Edge case: A Pod fails to reach itself via the Service IP
This might sound unlikely, but it does happen and it is supposed to work.
This can happen when the network is not properly configured for "hairpin"
traffic, usually when kube-proxy
is running in iptables
mode and Pods
are connected with bridge network. The Kubelet
exposes a hairpin-mode
flag that allows endpoints of a Service to loadbalance
back to themselves if they try to access their own Service VIP. The
hairpin-mode
flag must either be set to hairpin-veth
or
promiscuous-bridge
.
The common steps to trouble shoot this are as follows:
- Confirm
hairpin-mode
is set tohairpin-veth
orpromiscuous-bridge
. You should see something like the below.hairpin-mode
is set topromiscuous-bridge
in the following example.
ps auxw | grep kubelet
root 3392 1.1 0.8 186804 65208 ? Sl 00:51 11:11 /usr/local/bin/kubelet --enable-debugging-handlers=true --config=/etc/kubernetes/manifests --allow-privileged=True --v=4 --cluster-dns=10.0.0.10 --cluster-domain=cluster.local --configure-cbr0=true --cgroup-root=/ --system-cgroups=/system --hairpin-mode=promiscuous-bridge --runtime-cgroups=/docker-daemon --kubelet-cgroups=/kubelet --babysit-daemons=true --max-pods=110 --serialize-image-pulls=false --outofdisk-transition-frequency=0
- Confirm the effective
hairpin-mode
. To do this, you'll have to look at kubelet log. Accessing the logs depends on your Node OS. On some OSes it is a file, such as /var/log/kubelet.log, while other OSes usejournalctl
to access logs. Please be noted that the effective hairpin mode may not match--hairpin-mode
flag due to compatibility. Check if there is any log lines with key wordhairpin
in kubelet.log. There should be log lines indicating the effective hairpin mode, like something below.
I0629 00:51:43.648698 3252 kubelet.go:380] Hairpin mode set to "promiscuous-bridge"
- If the effective hairpin mode is
hairpin-veth
, ensure theKubelet
has the permission to operate in/sys
on node. If everything works properly, you should see something like:
for intf in /sys/devices/virtual/net/cbr0/brif/*; do cat $intf/hairpin_mode; done
1
1
1
1
- If the effective hairpin mode is
promiscuous-bridge
, ensureKubelet
has the permission to manipulate linux bridge on node. Ifcbr0
bridge is used and configured properly, you should see:
ifconfig cbr0 |grep PROMISC
UP BROADCAST RUNNING PROMISC MULTICAST MTU:1460 Metric:1
- Seek help if none of above works out.
Seek help
If you get this far, something very strange is happening. Your Service is
running, has Endpoints, and your Pods are actually serving. You have DNS
working, and kube-proxy
does not seem to be misbehaving. And yet your
Service is not working. Please let us know what is going on, so we can help
investigate!
Contact us on Slack or Forum or GitHub.
What's next
Visit troubleshooting document for more information.
8 - Debugging Kubernetes nodes with crictl
Kubernetes v1.11 [stable]
crictl
is a command-line interface for CRI-compatible container runtimes.
You can use it to inspect and debug container runtimes and applications on a
Kubernetes node. crictl
and its source are hosted in the
cri-tools repository.
Before you begin
crictl
requires a Linux operating system with a CRI runtime.
Installing crictl
You can download a compressed archive crictl
from the cri-tools release
page, for several
different architectures. Download the version that corresponds to your version
of Kubernetes. Extract it and move it to a location on your system path, such as
/usr/local/bin/
.
General usage
The crictl
command has several subcommands and runtime flags. Use
crictl help
or crictl <subcommand> help
for more details.
crictl
connects to unix:///var/run/dockershim.sock
by default. For other
runtimes, you can set the endpoint in multiple different ways:
- By setting flags
--runtime-endpoint
and--image-endpoint
- By setting environment variables
CONTAINER_RUNTIME_ENDPOINT
andIMAGE_SERVICE_ENDPOINT
- By setting the endpoint in the config file
--config=/etc/crictl.yaml
You can also specify timeout values when connecting to the server and enable or
disable debugging, by specifying timeout
or debug
values in the configuration
file or using the --timeout
and --debug
command-line flags.
To view or edit the current configuration, view or edit the contents of /etc/crictl.yaml
.
cat /etc/crictl.yaml
runtime-endpoint: unix:///var/run/dockershim.sock
image-endpoint: unix:///var/run/dockershim.sock
timeout: 10
debug: true
Example crictl commands
The following examples show some crictl
commands and example output.
Warning: If you usecrictl
to create pod sandboxes or containers on a running Kubernetes cluster, the Kubelet will eventually delete them.crictl
is not a general purpose workflow tool, but a tool that is useful for debugging.
List pods
List all pods:
crictl pods
The output is similar to this:
POD ID CREATED STATE NAME NAMESPACE ATTEMPT
926f1b5a1d33a About a minute ago Ready sh-84d7dcf559-4r2gq default 0
4dccb216c4adb About a minute ago Ready nginx-65899c769f-wv2gp default 0
a86316e96fa89 17 hours ago Ready kube-proxy-gblk4 kube-system 0
919630b8f81f1 17 hours ago Ready nvidia-device-plugin-zgbbv kube-system 0
List pods by name:
crictl pods --name nginx-65899c769f-wv2gp
The output is similar to this:
POD ID CREATED STATE NAME NAMESPACE ATTEMPT
4dccb216c4adb 2 minutes ago Ready nginx-65899c769f-wv2gp default 0
List pods by label:
crictl pods --label run=nginx
The output is similar to this:
POD ID CREATED STATE NAME NAMESPACE ATTEMPT
4dccb216c4adb 2 minutes ago Ready nginx-65899c769f-wv2gp default 0
List images
List all images:
crictl images
The output is similar to this:
IMAGE TAG IMAGE ID SIZE
busybox latest 8c811b4aec35f 1.15MB
k8s-gcrio.azureedge.net/hyperkube-amd64 v1.10.3 e179bbfe5d238 665MB
k8s-gcrio.azureedge.net/pause-amd64 3.1 da86e6ba6ca19 742kB
nginx latest cd5239a0906a6 109MB
List images by repository:
crictl images nginx
The output is similar to this:
IMAGE TAG IMAGE ID SIZE
nginx latest cd5239a0906a6 109MB
Only list image IDs:
crictl images -q
The output is similar to this:
sha256:8c811b4aec35f259572d0f79207bc0678df4c736eeec50bc9fec37ed936a472a
sha256:e179bbfe5d238de6069f3b03fccbecc3fb4f2019af741bfff1233c4d7b2970c5
sha256:da86e6ba6ca197bf6bc5e9d900febd906b133eaa4750e6bed647b0fbe50ed43e
sha256:cd5239a0906a6ccf0562354852fae04bc5b52d72a2aff9a871ddb6bd57553569
List containers
List all containers:
crictl ps -a
The output is similar to this:
CONTAINER ID IMAGE CREATED STATE NAME ATTEMPT
1f73f2d81bf98 busybox@sha256:141c253bc4c3fd0a201d32dc1f493bcf3fff003b6df416dea4f41046e0f37d47 7 minutes ago Running sh 1
9c5951df22c78 busybox@sha256:141c253bc4c3fd0a201d32dc1f493bcf3fff003b6df416dea4f41046e0f37d47 8 minutes ago Exited sh 0
87d3992f84f74 nginx@sha256:d0a8828cccb73397acb0073bf34f4d7d8aa315263f1e7806bf8c55d8ac139d5f 8 minutes ago Running nginx 0
1941fb4da154f k8s-gcrio.azureedge.net/hyperkube-amd64@sha256:00d814b1f7763f4ab5be80c58e98140dfc69df107f253d7fdd714b30a714260a 18 hours ago Running kube-proxy 0
List running containers:
crictl ps
The output is similar to this:
CONTAINER ID IMAGE CREATED STATE NAME ATTEMPT
1f73f2d81bf98 busybox@sha256:141c253bc4c3fd0a201d32dc1f493bcf3fff003b6df416dea4f41046e0f37d47 6 minutes ago Running sh 1
87d3992f84f74 nginx@sha256:d0a8828cccb73397acb0073bf34f4d7d8aa315263f1e7806bf8c55d8ac139d5f 7 minutes ago Running nginx 0
1941fb4da154f k8s-gcrio.azureedge.net/hyperkube-amd64@sha256:00d814b1f7763f4ab5be80c58e98140dfc69df107f253d7fdd714b30a714260a 17 hours ago Running kube-proxy 0
Execute a command in a running container
crictl exec -i -t 1f73f2d81bf98 ls
The output is similar to this:
bin dev etc home proc root sys tmp usr var
Get a container's logs
Get all container logs:
crictl logs 87d3992f84f74
The output is similar to this:
10.240.0.96 - - [06/Jun/2018:02:45:49 +0000] "GET / HTTP/1.1" 200 612 "-" "curl/7.47.0" "-"
10.240.0.96 - - [06/Jun/2018:02:45:50 +0000] "GET / HTTP/1.1" 200 612 "-" "curl/7.47.0" "-"
10.240.0.96 - - [06/Jun/2018:02:45:51 +0000] "GET / HTTP/1.1" 200 612 "-" "curl/7.47.0" "-"
Get only the latest N
lines of logs:
crictl logs --tail=1 87d3992f84f74
The output is similar to this:
10.240.0.96 - - [06/Jun/2018:02:45:51 +0000] "GET / HTTP/1.1" 200 612 "-" "curl/7.47.0" "-"
Run a pod sandbox
Using crictl
to run a pod sandbox is useful for debugging container runtimes.
On a running Kubernetes cluster, the sandbox will eventually be stopped and
deleted by the Kubelet.
Create a JSON file like the following:
{ "metadata": { "name": "nginx-sandbox", "namespace": "default", "attempt": 1, "uid": "hdishd83djaidwnduwk28bcsb" }, "logDirectory": "/tmp", "linux": { } }
Use the
crictl runp
command to apply the JSON and run the sandbox.crictl runp pod-config.json
The ID of the sandbox is returned.
Create a container
Using crictl
to create a container is useful for debugging container runtimes.
On a running Kubernetes cluster, the sandbox will eventually be stopped and
deleted by the Kubelet.
Pull a busybox image
crictl pull busybox Image is up to date for busybox@sha256:141c253bc4c3fd0a201d32dc1f493bcf3fff003b6df416dea4f41046e0f37d47
Create configs for the pod and the container:
Pod config:
{ "metadata": { "name": "nginx-sandbox", "namespace": "default", "attempt": 1, "uid": "hdishd83djaidwnduwk28bcsb" }, "log_directory": "/tmp", "linux": { } }
Container config:
{ "metadata": { "name": "busybox" }, "image":{ "image": "busybox" }, "command": [ "top" ], "log_path":"busybox.log", "linux": { } }
Create the container, passing the ID of the previously-created pod, the container config file, and the pod config file. The ID of the container is returned.
crictl create f84dd361f8dc51518ed291fbadd6db537b0496536c1d2d6c05ff943ce8c9a54f container-config.json pod-config.json
List all containers and verify that the newly-created container has its state set to
Created
.crictl ps -a
The output is similar to this:
CONTAINER ID IMAGE CREATED STATE NAME ATTEMPT 3e025dd50a72d busybox 32 seconds ago Created busybox 0
Start a container
To start a container, pass its ID to crictl start
:
crictl start 3e025dd50a72d956c4f14881fbb5b1080c9275674e95fb67f965f6478a957d60
The output is similar to this:
3e025dd50a72d956c4f14881fbb5b1080c9275674e95fb67f965f6478a957d60
Check the container has its state set to Running
.
crictl ps
The output is similar to this:
CONTAINER ID IMAGE CREATED STATE NAME ATTEMPT
3e025dd50a72d busybox About a minute ago Running busybox 0
See kubernetes-sigs/cri-tools for more information.
Mapping from docker cli to crictl
The exact versions for below mapping table are for docker cli v1.40 and crictl v1.19.0. Please note that the list is not exhaustive. For example, it doesn't include experimental commands of docker cli.
Note: The output format of CRICTL is similar to Docker CLI, despite some missing columns for some CLI. Make sure to check output for the specific command if your script output parsing.
Retrieve Debugging Information
docker cli | crictl | Description | Unsupported Features |
---|---|---|---|
attach | attach | Attach to a running container | --detach-keys , --sig-proxy |
exec | exec | Run a command in a running container | --privileged , --user , --detach-keys |
images | images | List images | |
info | info | Display system-wide information | |
inspect | inspect , inspecti | Return low-level information on a container, image or task | |
logs | logs | Fetch the logs of a container | --details |
ps | ps | List containers | |
stats | stats | Display a live stream of container(s) resource usage statistics | Column: NET/BLOCK I/O, PIDs |
version | version | Show the runtime (Docker, ContainerD, or others) version information |
Perform Changes
docker cli | crictl | Description | Unsupported Features |
---|---|---|---|
create | create | Create a new container | |
kill | stop (timeout = 0) | Kill one or more running container | --signal |
pull | pull | Pull an image or a repository from a registry | --all-tags , --disable-content-trust |
rm | rm | Remove one or more containers | |
rmi | rmi | Remove one or more images | |
run | run | Run a command in a new container | |
start | start | Start one or more stopped containers | --detach-keys |
stop | stop | Stop one or more running containers | |
update | update | Update configuration of one or more containers | --restart , --blkio-weight and some other resource limit not supported by CRI. |
Supported only in crictl
crictl | Description |
---|---|
imagefsinfo | Return image filesystem info |
inspectp | Display the status of one or more pods |
port-forward | Forward local port to a pod |
pods | List pods |
runp | Run a new pod |
rmp | Remove one or more pods |
stopp | Stop one or more running pods |
9 - Determine the Reason for Pod Failure
This page shows how to write and read a Container termination message.
Termination messages provide a way for containers to write information about fatal events to a location where it can be easily retrieved and surfaced by tools like dashboards and monitoring software. In most cases, information that you put in a termination message should also be written to the general Kubernetes logs.
Before you begin
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
To check the version, enterkubectl version
.Writing and reading a termination message
In this exercise, you create a Pod that runs one container. The configuration file specifies a command that runs when the container starts.
apiVersion: v1
kind: Pod
metadata:
name: termination-demo
spec:
containers:
- name: termination-demo-container
image: debian
command: ["/bin/sh"]
args: ["-c", "sleep 10 && echo Sleep expired > /dev/termination-log"]
Create a Pod based on the YAML configuration file:
kubectl apply -f https://k8s.io/examples/debug/termination.yaml
In the YAML file, in the
command
andargs
fields, you can see that the container sleeps for 10 seconds and then writes "Sleep expired" to the/dev/termination-log
file. After the container writes the "Sleep expired" message, it terminates.Display information about the Pod:
kubectl get pod termination-demo
Repeat the preceding command until the Pod is no longer running.
Display detailed information about the Pod:
kubectl get pod termination-demo --output=yaml
The output includes the "Sleep expired" message:
apiVersion: v1 kind: Pod ... lastState: terminated: containerID: ... exitCode: 0 finishedAt: ... message: | Sleep expired ...
Use a Go template to filter the output so that it includes only the termination message:
kubectl get pod termination-demo -o go-template="{{range .status.containerStatuses}}{{.lastState.terminated.message}}{{end}}"
Customizing the termination message
Kubernetes retrieves termination messages from the termination message file
specified in the terminationMessagePath
field of a Container, which has a default
value of /dev/termination-log
. By customizing this field, you can tell Kubernetes
to use a different file. Kubernetes use the contents from the specified file to
populate the Container's status message on both success and failure.
The termination message is intended to be brief final status, such as an assertion failure message.
The kubelet truncates messages that are longer than 4096 bytes. The total message length across all
containers will be limited to 12KiB. The default termination message path is /dev/termination-log
.
You cannot set the termination message path after a Pod is launched
In the following example, the container writes termination messages to
/tmp/my-log
for Kubernetes to retrieve:
apiVersion: v1
kind: Pod
metadata:
name: msg-path-demo
spec:
containers:
- name: msg-path-demo-container
image: debian
terminationMessagePath: "/tmp/my-log"
Moreover, users can set the terminationMessagePolicy
field of a Container for
further customization. This field defaults to "File
" which means the termination
messages are retrieved only from the termination message file. By setting the
terminationMessagePolicy
to "FallbackToLogsOnError
", you can tell Kubernetes
to use the last chunk of container log output if the termination message file
is empty and the container exited with an error. The log output is limited to
2048 bytes or 80 lines, whichever is smaller.
What's next
- See the
terminationMessagePath
field in Container. - Learn about retrieving logs.
- Learn about Go templates.
10 - Developing and debugging services locally
Kubernetes applications usually consist of multiple, separate services, each running in its own container. Developing and debugging these services on a remote Kubernetes cluster can be cumbersome, requiring you to get a shell on a running container and running your tools inside the remote shell.
telepresence
is a tool to ease the process of developing and debugging services locally, while proxying the service to a remote Kubernetes cluster. Using telepresence
allows you to use custom tools, such as a debugger and IDE, for a local service and provides the service full access to ConfigMap, secrets, and the services running on the remote cluster.
This document describes using telepresence
to develop and debug services running on a remote cluster locally.
Before you begin
- Kubernetes cluster is installed
kubectl
is configured to communicate with the cluster- Telepresence is installed
Getting a shell on a remote cluster
Open a terminal and run telepresence
with no arguments to get a telepresence
shell. This shell runs locally, giving you full access to your local filesystem.
The telepresence
shell can be used in a variety of ways. For example, write a shell script on your laptop, and run it directly from the shell in real time. You can do this on a remote shell as well, but you might not be able to use your preferred code editor, and the script is deleted when the container is terminated.
Enter exit
to quit and close the shell.
Developing or debugging an existing service
When developing an application on Kubernetes, you typically program or debug a single service. The service might require access to other services for testing and debugging. One option is to use the continuous deployment pipeline, but even the fastest deployment pipeline introduces a delay in the program or debug cycle.
Use the --swap-deployment
option to swap an existing deployment with the Telepresence proxy. Swapping allows you to run a service locally and connect to the remote Kubernetes cluster. The services in the remote cluster can now access the locally running instance.
To run telepresence with --swap-deployment
, enter:
telepresence --swap-deployment $DEPLOYMENT_NAME
where $DEPLOYMENT_NAME is the name of your existing deployment.
Running this command spawns a shell. In the shell, start your service. You can then make edits to the source code locally, save, and see the changes take effect immediately. You can also run your service in a debugger, or any other local development tool.
What's next
If you're interested in a hands-on tutorial, check out this tutorial that walks through locally developing the Guestbook application on Google Kubernetes Engine.
Telepresence has numerous proxying options, depending on your situation.
For further reading, visit the Telepresence website.
11 - Get a Shell to a Running Container
This page shows how to use kubectl exec
to get a shell to a
running container.
Before you begin
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
Getting a shell to a container
In this exercise, you create a Pod that has one container. The container runs the nginx image. Here is the configuration file for the Pod:
apiVersion: v1
kind: Pod
metadata:
name: shell-demo
spec:
volumes:
- name: shared-data
emptyDir: {}
containers:
- name: nginx
image: nginx
volumeMounts:
- name: shared-data
mountPath: /usr/share/nginx/html
hostNetwork: true
dnsPolicy: Default
Create the Pod:
kubectl apply -f https://k8s.io/examples/application/shell-demo.yaml
Verify that the container is running:
kubectl get pod shell-demo
Get a shell to the running container:
kubectl exec --stdin --tty shell-demo -- /bin/bash
Note: The double dash (--
) separates the arguments you want to pass to the command from the kubectl arguments.
In your shell, list the root directory:
# Run this inside the container
ls /
In your shell, experiment with other commands. Here are some examples:
# You can run these example commands inside the container
ls /
cat /proc/mounts
cat /proc/1/maps
apt-get update
apt-get install -y tcpdump
tcpdump
apt-get install -y lsof
lsof
apt-get install -y procps
ps aux
ps aux | grep nginx
Writing the root page for nginx
Look again at the configuration file for your Pod. The Pod
has an emptyDir
volume, and the container mounts the volume
at /usr/share/nginx/html
.
In your shell, create an index.html
file in the /usr/share/nginx/html
directory:
# Run this inside the container
echo 'Hello shell demo' > /usr/share/nginx/html/index.html
In your shell, send a GET request to the nginx server:
# Run this in the shell inside your container
apt-get update
apt-get install curl
curl http://localhost/
The output shows the text that you wrote to the index.html
file:
Hello shell demo
When you are finished with your shell, enter exit
.
exit # To quit the shell in the container
Running individual commands in a container
In an ordinary command window, not your shell, list the environment variables in the running container:
kubectl exec shell-demo env
Experiment with running other commands. Here are some examples:
kubectl exec shell-demo -- ps aux
kubectl exec shell-demo -- ls /
kubectl exec shell-demo -- cat /proc/1/mounts
Opening a shell when a Pod has more than one container
If a Pod has more than one container, use --container
or -c
to
specify a container in the kubectl exec
command. For example,
suppose you have a Pod named my-pod, and the Pod has two containers
named main-app and helper-app. The following command would open a
shell to the main-app container.
kubectl exec -i -t my-pod --container main-app -- /bin/bash
Note: The short options-i
and-t
are the same as the long options--stdin
and--tty
What's next
- Read about kubectl exec
12 - Monitor Node Health
Node Problem Detector is a daemon for monitoring and reporting about a node's health.
You can run Node Problem Detector as a DaemonSet
or as a standalone daemon.
Node Problem Detector collects information about node problems from various daemons
and reports these conditions to the API server as NodeCondition
and Event.
To learn how to install and use Node Problem Detector, see Node Problem Detector project documentation.
Before you begin
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
Limitations
Node Problem Detector only supports file based kernel log. Log tools such as
journald
are not supported.Node Problem Detector uses the kernel log format for reporting kernel issues. To learn how to extend the kernel log format, see Add support for another log format.
Enabling Node Problem Detector
Some cloud providers enable Node Problem Detector as an Addon.
You can also enable Node Problem Detector with kubectl
or by creating an Addon pod.
Using kubectl to enable Node Problem Detector
kubectl
provides the most flexible management of Node Problem Detector.
You can overwrite the default configuration to fit it into your environment or
to detect customized node problems. For example:
Create a Node Problem Detector configuration similar to
node-problem-detector.yaml
:apiVersion: apps/v1 kind: DaemonSet metadata: name: node-problem-detector-v0.1 namespace: kube-system labels: k8s-app: node-problem-detector version: v0.1 kubernetes.io/cluster-service: "true" spec: selector: matchLabels: k8s-app: node-problem-detector version: v0.1 kubernetes.io/cluster-service: "true" template: metadata: labels: k8s-app: node-problem-detector version: v0.1 kubernetes.io/cluster-service: "true" spec: hostNetwork: true containers: - name: node-problem-detector image: k8s.gcr.io/node-problem-detector:v0.1 securityContext: privileged: true resources: limits: cpu: "200m" memory: "100Mi" requests: cpu: "20m" memory: "20Mi" volumeMounts: - name: log mountPath: /log readOnly: true volumes: - name: log hostPath: path: /var/log/
Note: You should verify that the system log directory is right for your operating system distribution.Start node problem detector with
kubectl
:kubectl apply -f https://k8s.io/examples/debug/node-problem-detector.yaml
Using an Addon pod to enable Node Problem Detector
If you are using a custom cluster bootstrap solution and don't need to overwrite the default configuration, you can leverage the Addon pod to further automate the deployment.
Create node-problem-detector.yaml
, and save the configuration in the Addon pod's
directory /etc/kubernetes/addons/node-problem-detector
on a control plane node.
Overwrite the configuration
The default configuration is embedded when building the Docker image of Node Problem Detector.
However, you can use a ConfigMap
to overwrite the configuration:
Change the configuration files in
config/
Create the
ConfigMap
node-problem-detector-config
:kubectl create configmap node-problem-detector-config --from-file=config/
Change the
node-problem-detector.yaml
to use theConfigMap
:apiVersion: apps/v1 kind: DaemonSet metadata: name: node-problem-detector-v0.1 namespace: kube-system labels: k8s-app: node-problem-detector version: v0.1 kubernetes.io/cluster-service: "true" spec: selector: matchLabels: k8s-app: node-problem-detector version: v0.1 kubernetes.io/cluster-service: "true" template: metadata: labels: k8s-app: node-problem-detector version: v0.1 kubernetes.io/cluster-service: "true" spec: hostNetwork: true containers: - name: node-problem-detector image: k8s.gcr.io/node-problem-detector:v0.1 securityContext: privileged: true resources: limits: cpu: "200m" memory: "100Mi" requests: cpu: "20m" memory: "20Mi" volumeMounts: - name: log mountPath: /log readOnly: true - name: config # Overwrite the config/ directory with ConfigMap volume mountPath: /config readOnly: true volumes: - name: log hostPath: path: /var/log/ - name: config # Define ConfigMap volume configMap: name: node-problem-detector-config
Recreate the Node Problem Detector with the new configuration file:
# If you have a node-problem-detector running, delete before recreating kubectl delete -f https://k8s.io/examples/debug/node-problem-detector.yaml kubectl apply -f https://k8s.io/examples/debug/node-problem-detector-configmap.yaml
Note: This approach only applies to a Node Problem Detector started withkubectl
.
Overwriting a configuration is not supported if a Node Problem Detector runs as a cluster Addon.
The Addon manager does not support ConfigMap
.
Kernel Monitor
Kernel Monitor is a system log monitor daemon supported in the Node Problem Detector. Kernel monitor watches the kernel log and detects known kernel issues following predefined rules.
The Kernel Monitor matches kernel issues according to a set of predefined rule list in
config/kernel-monitor.json
. The rule list is extensible. You can expand the rule list by overwriting the
configuration.
Add new NodeConditions
To support a new NodeCondition
, create a condition definition within the conditions
field in
config/kernel-monitor.json
, for example:
{
"type": "NodeConditionType",
"reason": "CamelCaseDefaultNodeConditionReason",
"message": "arbitrary default node condition message"
}
Detect new problems
To detect new problems, you can extend the rules
field in config/kernel-monitor.json
with a new rule definition:
{
"type": "temporary/permanent",
"condition": "NodeConditionOfPermanentIssue",
"reason": "CamelCaseShortReason",
"message": "regexp matching the issue in the kernel log"
}
Configure path for the kernel log device
Check your kernel log path location in your operating system (OS) distribution.
The Linux kernel log device is usually presented as /dev/kmsg
. However, the log path location varies by OS distribution.
The log
field in config/kernel-monitor.json
represents the log path inside the container.
You can configure the log
field to match the device path as seen by the Node Problem Detector.
Add support for another log format
Kernel monitor uses the
Translator
plugin to translate the internal data structure of the kernel log.
You can implement a new translator for a new log format.
Recommendations and restrictions
It is recommended to run the Node Problem Detector in your cluster to monitor node health. When running the Node Problem Detector, you can expect extra resource overhead on each node. Usually this is fine, because:
- The kernel log grows relatively slowly.
- A resource limit is set for the Node Problem Detector.
- Even under high load, the resource usage is acceptable. For more information, see the Node Problem Detector benchmark result.
13 - Resource metrics pipeline
Resource usage metrics, such as container CPU and memory usage,
are available in Kubernetes through the Metrics API. These metrics can be accessed either directly
by the user with the kubectl top
command, or by a controller in the cluster, for example
Horizontal Pod Autoscaler, to make decisions.
The Metrics API
Through the Metrics API, you can get the amount of resource currently used by a given node or a given pod. This API doesn't store the metric values, so it's not possible, for example, to get the amount of resources used by a given node 10 minutes ago.
The API is no different from any other API:
- it is discoverable through the same endpoint as the other Kubernetes APIs under the path:
/apis/metrics.k8s.io/
- it offers the same security, scalability, and reliability guarantees
The API is defined in k8s.io/metrics repository. You can find more information about the API there.
Note: The API requires the metrics server to be deployed in the cluster. Otherwise it will be not available.
Measuring Resource Usage
CPU
CPU is reported as the average usage, in CPU cores, over a period of time. This value is derived by taking a rate over a cumulative CPU counter provided by the kernel (in both Linux and Windows kernels). The kubelet chooses the window for the rate calculation.
Memory
Memory is reported as the working set, in bytes, at the instant the metric was collected. In an ideal world, the "working set" is the amount of memory in-use that cannot be freed under memory pressure. However, calculation of the working set varies by host OS, and generally makes heavy use of heuristics to produce an estimate. It includes all anonymous (non-file-backed) memory since Kubernetes does not support swap. The metric typically also includes some cached (file-backed) memory, because the host OS cannot always reclaim such pages.
Metrics Server
Metrics Server is a cluster-wide aggregator of resource usage data.
By default, it is deployed in clusters created by kube-up.sh
script
as a Deployment object. If you use a different Kubernetes setup mechanism, you can deploy it using the provided
deployment components.yaml file.
Metrics Server collects metrics from the Summary API, exposed by Kubelet on each node, and is registered with the main API server via Kubernetes aggregator.
Learn more about the metrics server in the design doc.
14 - Tools for Monitoring Resources
To scale an application and provide a reliable service, you need to understand how the application behaves when it is deployed. You can examine application performance in a Kubernetes cluster by examining the containers, pods, services, and the characteristics of the overall cluster. Kubernetes provides detailed information about an application's resource usage at each of these levels. This information allows you to evaluate your application's performance and where bottlenecks can be removed to improve overall performance.
In Kubernetes, application monitoring does not depend on a single monitoring solution. On new clusters, you can use resource metrics or full metrics pipelines to collect monitoring statistics.
Resource metrics pipeline
The resource metrics pipeline provides a limited set of metrics related to
cluster components such as the
Horizontal Pod Autoscaler
controller, as well as the kubectl top
utility.
These metrics are collected by the lightweight, short-term, in-memory
metrics-server and
are exposed via the metrics.k8s.io
API.
metrics-server discovers all nodes on the cluster and
queries each node's
kubelet for CPU and
memory usage. The kubelet acts as a bridge between the Kubernetes master and
the nodes, managing the pods and containers running on a machine. The kubelet
translates each pod into its constituent containers and fetches individual
container usage statistics from the container runtime through the container
runtime interface. The kubelet fetches this information from the integrated
cAdvisor for the legacy Docker integration. It then exposes the aggregated pod
resource usage statistics through the metrics-server Resource Metrics API.
This API is served at /metrics/resource/v1beta1
on the kubelet's authenticated and
read-only ports.
Full metrics pipeline
A full metrics pipeline gives you access to richer metrics. Kubernetes can
respond to these metrics by automatically scaling or adapting the cluster
based on its current state, using mechanisms such as the Horizontal Pod
Autoscaler. The monitoring pipeline fetches metrics from the kubelet and
then exposes them to Kubernetes via an adapter by implementing either the
custom.metrics.k8s.io
or external.metrics.k8s.io
API.
Prometheus, a CNCF project, can natively monitor Kubernetes, nodes, and Prometheus itself. Full metrics pipeline projects that are not part of the CNCF are outside the scope of Kubernetes documentation.
15 - Troubleshoot Applications
This guide is to help users debug applications that are deployed into Kubernetes and not behaving correctly. This is not a guide for people who want to debug their cluster. For that you should check out this guide.
Diagnosing the problem
The first step in troubleshooting is triage. What is the problem? Is it your Pods, your Replication Controller or your Service?
Debugging Pods
The first step in debugging a Pod is taking a look at it. Check the current state of the Pod and recent events with the following command:
kubectl describe pods ${POD_NAME}
Look at the state of the containers in the pod. Are they all Running
? Have there been recent restarts?
Continue debugging depending on the state of the pods.
My pod stays pending
If a Pod is stuck in Pending
it means that it can not be scheduled onto a node. Generally this is because
there are insufficient resources of one type or another that prevent scheduling. Look at the output of the
kubectl describe ...
command above. There should be messages from the scheduler about why it can not schedule
your pod. Reasons include:
You don't have enough resources: You may have exhausted the supply of CPU or Memory in your cluster, in this case you need to delete Pods, adjust resource requests, or add new nodes to your cluster. See Compute Resources document for more information.
You are using
hostPort
: When you bind a Pod to ahostPort
there are a limited number of places that pod can be scheduled. In most cases,hostPort
is unnecessary, try using a Service object to expose your Pod. If you do requirehostPort
then you can only schedule as many Pods as there are nodes in your Kubernetes cluster.
My pod stays waiting
If a Pod is stuck in the Waiting
state, then it has been scheduled to a worker node, but it can't run on that machine.
Again, the information from kubectl describe ...
should be informative. The most common cause of Waiting
pods is a failure to pull the image. There are three things to check:
- Make sure that you have the name of the image correct.
- Have you pushed the image to the repository?
- Run a manual
docker pull <image>
on your machine to see if the image can be pulled.
My pod is crashing or otherwise unhealthy
Once your pod has been scheduled, the methods described in Debug Running Pods are available for debugging.
My pod is running but not doing what I told it to do
If your pod is not behaving as you expected, it may be that there was an error in your
pod description (e.g. mypod.yaml
file on your local machine), and that the error
was silently ignored when you created the pod. Often a section of the pod description
is nested incorrectly, or a key name is typed incorrectly, and so the key is ignored.
For example, if you misspelled command
as commnd
then the pod will be created but
will not use the command line you intended it to use.
The first thing to do is to delete your pod and try creating it again with the --validate
option.
For example, run kubectl apply --validate -f mypod.yaml
.
If you misspelled command
as commnd
then will give an error like this:
I0805 10:43:25.129850 46757 schema.go:126] unknown field: commnd
I0805 10:43:25.129973 46757 schema.go:129] this may be a false alarm, see https://github.com/kubernetes/kubernetes/issues/6842
pods/mypod
The next thing to check is whether the pod on the apiserver
matches the pod you meant to create (e.g. in a yaml file on your local machine).
For example, run kubectl get pods/mypod -o yaml > mypod-on-apiserver.yaml
and then
manually compare the original pod description, mypod.yaml
with the one you got
back from apiserver, mypod-on-apiserver.yaml
. There will typically be some
lines on the "apiserver" version that are not on the original version. This is
expected. However, if there are lines on the original that are not on the apiserver
version, then this may indicate a problem with your pod spec.
Debugging Replication Controllers
Replication controllers are fairly straightforward. They can either create Pods or they can't. If they can't create pods, then please refer to the instructions above to debug your pods.
You can also use kubectl describe rc ${CONTROLLER_NAME}
to introspect events related to the replication
controller.
Debugging Services
Services provide load balancing across a set of pods. There are several common problems that can make Services not work properly. The following instructions should help debug Service problems.
First, verify that there are endpoints for the service. For every Service object, the apiserver makes an endpoints
resource available.
You can view this resource with:
kubectl get endpoints ${SERVICE_NAME}
Make sure that the endpoints match up with the number of pods that you expect to be members of your service. For example, if your Service is for an nginx container with 3 replicas, you would expect to see three different IP addresses in the Service's endpoints.
My service is missing endpoints
If you are missing endpoints, try listing pods using the labels that Service uses. Imagine that you have a Service where the labels are:
...
spec:
- selector:
name: nginx
type: frontend
You can use:
kubectl get pods --selector=name=nginx,type=frontend
to list pods that match this selector. Verify that the list matches the Pods that you expect to provide your Service.
Verify that the pod's containerPort
matches up with the Service's targetPort
Network traffic is not forwarded
Please see debugging service for more information.
What's next
If none of the above solves your problem, follow the instructions in
Debugging Service document
to make sure that your Service
is running, has Endpoints
, and your Pods
are
actually serving; you have DNS working, iptables rules installed, and kube-proxy
does not seem to be misbehaving.
You may also visit troubleshooting document for more information.
16 - Troubleshoot Clusters
This doc is about cluster troubleshooting; we assume you have already ruled out your application as the root cause of the problem you are experiencing. See the application troubleshooting guide for tips on application debugging. You may also visit troubleshooting document for more information.
Listing your cluster
The first thing to debug in your cluster is if your nodes are all registered correctly.
Run
kubectl get nodes
And verify that all of the nodes you expect to see are present and that they are all in the Ready
state.
To get detailed information about the overall health of your cluster, you can run:
kubectl cluster-info dump
Looking at logs
For now, digging deeper into the cluster requires logging into the relevant machines. Here are the locations
of the relevant log files. (note that on systemd-based systems, you may need to use journalctl
instead)
Master
/var/log/kube-apiserver.log
- API Server, responsible for serving the API/var/log/kube-scheduler.log
- Scheduler, responsible for making scheduling decisions/var/log/kube-controller-manager.log
- Controller that manages replication controllers
Worker Nodes
/var/log/kubelet.log
- Kubelet, responsible for running containers on the node/var/log/kube-proxy.log
- Kube Proxy, responsible for service load balancing
A general overview of cluster failure modes
This is an incomplete list of things that could go wrong, and how to adjust your cluster setup to mitigate the problems.
Root causes:
- VM(s) shutdown
- Network partition within cluster, or between cluster and users
- Crashes in Kubernetes software
- Data loss or unavailability of persistent storage (e.g. GCE PD or AWS EBS volume)
- Operator error, for example misconfigured Kubernetes software or application software
Specific scenarios:
- Apiserver VM shutdown or apiserver crashing
- Results
- unable to stop, update, or start new pods, services, replication controller
- existing pods and services should continue to work normally, unless they depend on the Kubernetes API
- Results
- Apiserver backing storage lost
- Results
- apiserver should fail to come up
- kubelets will not be able to reach it but will continue to run the same pods and provide the same service proxying
- manual recovery or recreation of apiserver state necessary before apiserver is restarted
- Results
- Supporting services (node controller, replication controller manager, scheduler, etc) VM shutdown or crashes
- currently those are colocated with the apiserver, and their unavailability has similar consequences as apiserver
- in future, these will be replicated as well and may not be co-located
- they do not have their own persistent state
- Individual node (VM or physical machine) shuts down
- Results
- pods on that Node stop running
- Results
- Network partition
- Results
- partition A thinks the nodes in partition B are down; partition B thinks the apiserver is down. (Assuming the master VM ends up in partition A.)
- Results
- Kubelet software fault
- Results
- crashing kubelet cannot start new pods on the node
- kubelet might delete the pods or not
- node marked unhealthy
- replication controllers start new pods elsewhere
- Results
- Cluster operator error
- Results
- loss of pods, services, etc
- lost of apiserver backing store
- users unable to read API
- etc.
- Results
Mitigations:
Action: Use IaaS provider's automatic VM restarting feature for IaaS VMs
- Mitigates: Apiserver VM shutdown or apiserver crashing
- Mitigates: Supporting services VM shutdown or crashes
Action: Use IaaS providers reliable storage (e.g. GCE PD or AWS EBS volume) for VMs with apiserver+etcd
- Mitigates: Apiserver backing storage lost
Action: Use high-availability configuration
- Mitigates: Control plane node shutdown or control plane components (scheduler, API server, controller-manager) crashing
- Will tolerate one or more simultaneous node or component failures
- Mitigates: API server backing storage (i.e., etcd's data directory) lost
- Assumes HA (highly-available) etcd configuration
- Mitigates: Control plane node shutdown or control plane components (scheduler, API server, controller-manager) crashing
Action: Snapshot apiserver PDs/EBS-volumes periodically
- Mitigates: Apiserver backing storage lost
- Mitigates: Some cases of operator error
- Mitigates: Some cases of Kubernetes software fault
Action: use replication controller and services in front of pods
- Mitigates: Node shutdown
- Mitigates: Kubelet software fault
Action: applications (containers) designed to tolerate unexpected restarts
- Mitigates: Node shutdown
- Mitigates: Kubelet software fault
17 - Troubleshooting
Sometimes things go wrong. This guide is aimed at making them right. It has two sections:
- Troubleshooting your application - Useful for users who are deploying code into Kubernetes and wondering why it is not working.
- Troubleshooting your cluster - Useful for cluster administrators and people whose Kubernetes cluster is unhappy.
You should also check the known issues for the release you're using.
Getting help
If your problem isn't answered by any of the guides above, there are variety of ways for you to get help from the Kubernetes community.
Questions
The documentation on this site has been structured to provide answers to a wide
range of questions. Concepts explain the Kubernetes
architecture and how each component works, while Setup provides
practical instructions for getting started. Tasks show how to
accomplish commonly used tasks, and Tutorials are more
comprehensive walkthroughs of real-world, industry-specific, or end-to-end
development scenarios. The Reference section provides
detailed documentation on the Kubernetes API
and command-line interfaces (CLIs), such as kubectl
.
Help! My question isn't covered! I need help now!
Stack Overflow
Someone else from the community may have already asked a similar question or may be able to help with your problem. The Kubernetes team will also monitor posts tagged Kubernetes. If there aren't any existing questions that help, please ask a new one!
Slack
Many people from the Kubernetes community hang out on Kubernetes Slack in the #kubernetes-users
channel.
Slack requires registration; you can request an invitation,
and registration is open to everyone). Feel free to come and ask any and all questions.
Once registered, access the Kubernetes organisation in Slack
via your web browser or via Slack's own dedicated app.
Once you are registered, browse the growing list of channels for various subjects of
interest. For example, people new to Kubernetes may also want to join the
#kubernetes-novice
channel. As another example, developers should join the
#kubernetes-dev
channel.
There are also many country specific / local language channels. Feel free to join these channels for localized support and info:
Country | Channels |
---|---|
China | #cn-users , #cn-events |
Finland | #fi-users |
France | #fr-users , #fr-events |
Germany | #de-users , #de-events |
India | #in-users , #in-events |
Italy | #it-users , #it-events |
Japan | #jp-users , #jp-events |
Korea | #kr-users |
Netherlands | #nl-users |
Norway | #norw-users |
Poland | #pl-users |
Russia | #ru-users |
Spain | #es-users |
Sweden | #se-users |
Turkey | #tr-users , #tr-events |
Forum
You're welcome to join the official Kubernetes Forum: discuss.kubernetes.io.
Bugs and feature requests
If you have what looks like a bug, or you would like to make a feature request, please use the GitHub issue tracking system.
Before you file an issue, please search existing issues to see if your issue is already covered.
If filing a bug, please include detailed information about how to reproduce the problem, such as:
- Kubernetes version:
kubectl version
- Cloud provider, OS distro, network configuration, and Docker version
- Steps to reproduce the problem